option for electric model More...
#include <cs_elec_model.h>
 Collaboration diagram for cs_elec_option_t:
 Collaboration diagram for cs_elec_option_t:| Data Fields | |
| int | ixkabe | 
| int | ntdcla | 
| int | irestrike | 
| cs_real_t | restrike_point [3] | 
| cs_real_t | crit_reca [5] | 
| int | ielcor | 
| int | modrec | 
| int | idreca | 
| int * | izreca | 
| cs_real_t | couimp | 
| cs_real_t | pot_diff | 
| cs_real_t | puisim | 
| cs_real_t | coejou | 
| cs_real_t | elcou | 
| cs_real_t | srrom | 
option for electric model
| coejou | 
coefficient for scaling
| couimp | 
Imposed current.
 With the electric arcs module, couimp is the target current intensity (  ) for the calculations with boundary condition tuning for the potential.
) for the calculations with boundary condition tuning for the potential.
 The target intensity will be reached if the boundary conditions are expressed using the variable pot_diff or if the initial boundary conditions are multiplied by the variable coejou.
 Useful with the electric arcs module if ielcor = 1. 
| crit_reca | 
Defines plane coordinates component used to calculate current in a plane.
 Useful if modrec = 2. 
| elcou | 
current in scaling plane
| idreca | 
Defines the current density component used to calculate current in a plane.
 Useful if modrec = 2. 
| ielcor | 
Indicate if scaling or not.
 When ielcor = 1, the boundary conditions for the potential will be tuned at each time step in order to reach a user-specified target dissipated power puisim (Joule effect) or a user-specified target current intensity couimp (electric arcs).
 The boundary condition tuning is controlled by subroutines elreca or Scaling parameters definition for electric model (cs_user_electric_scaling.c). 
| irestrike | 
Indicate if restrike or not
| ixkabe | 
Model for radiative properties
| izreca | 
Indicator for faces for scaling
| modrec | 
Model for scaling
| ntdcla | 
First iteration to take into account restrike model
| pot_diff | 
Potential difference.
 pot_diff is the potential difference (  ) which generates the current (and the Joule effect) for the calculations with boundary conditions tuning for the potential. This value is initialised set by the user (cs_user_parameters). It is then automatically tuned depending on the value of dissipated power (Joule effect module) or the intensity of current (electric arcs module). In order for the correct power or intensity to be reached, the boundary conditions for the potential must be expressed with pot_diff . The tuning can be controlled in cs_user_electric_scaling.
) which generates the current (and the Joule effect) for the calculations with boundary conditions tuning for the potential. This value is initialised set by the user (cs_user_parameters). It is then automatically tuned depending on the value of dissipated power (Joule effect module) or the intensity of current (electric arcs module). In order for the correct power or intensity to be reached, the boundary conditions for the potential must be expressed with pot_diff . The tuning can be controlled in cs_user_electric_scaling.
 Useful if ielcor = 1. 
| puisim | 
Imposed power.
 With the Joule effect module, puisim is the target dissipated power ($W$) for the calculations with boundary condition tuning for the potential.
 The target power will be reached if the boundary conditions are expressed using the variable pot_diff or if the initial boundary conditions are multiplied by the variable coejou . Useful with the Joule effect module if ielcor = 1. 
| restrike_point | 
Coordinates for restrike point
| srrom | 
Sub-relaxation coefficient for the density, following the formula:  Hence, with a zero value, there is no sub-relaxation.
 Hence, with a zero value, there is no sub-relaxation.